Exploring the High-z Frontier — Galaxies at z 6 and beyond Haojing Yan (Carnegie Observatories) Purple Mountain Observatory July 14, 2008 Haojing Yan (Carnegie Observatories) Purple Mountain Observatory July 14, 2008
Outline UV Luminosity Function of Galaxies at z 6 — LBG LF has a very steep faint-end slope Stellar Masses of Galaxies at z 6 — some high-mass, “old” galaxies already in place Implications for (HI) Reionization — dwarf galaxies did it! Unanswered Questions at z 6 — evolution of LF at the bright-end? Searching for Galaxies at z > 7-8
Part I LF of Galaxies at z 6 (5.5 z 6.5)
Reionization might have ended at z 6 (Fan et al. 2006, AJ, 132,117) ~ 1% is sufficient to create a complete GP-trough Practically, H still nearly fully ionized at z 6
Searching Techniques Lyman- Break Galaxy (LBG) “Dropout” Ly Emitter (LAE)
Surface Density Expectation Assuming non-evolving M* ( ) & faint-end slope (-1.6) from z=3 Using the z=5.60 galaxy in the HDF-N (Weymann et al. 1999) to fix the normalization Yan et al. 2002, ApJ, 580, 725
Simple Prediction Seems to Work Well Consistent with all observations up to 2003, including new results from the HST/ACS Different groups emphasized different aspects: Yan et al. (2003) Bouwens et al. (2003) Bunker et al. (2004) Dickinson et al. (2004)
Source(s) of Reionization Yan & Windhorst 2004, ApJ, 600, L1 Critical value from Madau, Haardt & Rees 1999 Contribution from reionizing sources Galaxies can account for the necessary reionizing photons, if the LF has a steep faint-end slope; dwarf galaxies are important contributors. Galaxies can account for the necessary reionizing photons, if the LF has a steep faint-end slope; dwarf galaxies are important contributors.
To z<30 mag, 108 i-dropouts found in the HUDF (Yan & Windhorst 2004, ApJ, 612, L93; YW04) Note: ~ 1.5 mag deeper than Bunker et al. (2004; MNRAS, 355, 374)
By pushing to the very limit of the HUDF, we start to be able to address the LF faint-end slope at z~6.
i’ z’ z’=29.23 z’=29.97 Detection Reliability at z>28.5 mag Level
z=5.83; Dickinson et al. (2004) z=5.9; Malhotra et al. (2005)
ACS Grism Observations of HUDF (GRAPES; Malhotra et al. 2005) z=6.0 z=6.1 z=6.4 GRAPES: i-dropouts success rate of ~ 90% in the HUDF to z~27.5 mag
Our HUDF z 6 candidate sample supports a very steep UV LF faint-end slope: α = -1.8 to -1.9 Dwarf galaxies can provide sufficient (re)ionizing photons at z 6 YW04 Constrain to the UV LF at z 6
Recent Result Confirms the Steep Faint-end Slope (Bouwens et al. 2006) 506 i-drops: UDF, UDF-Pars, GOODS But compare to YW04: M* = , * = 4.6x10 -4 /Mpc 3 4.6x10 -3 M sun /yr/Mpc 3 1.1x10 -2 M sun /yr/Mpc 3 SFR is still uncertain by 2x “Lilly-Madau Diagram”
Luminosity Function of z 6 LAE LAE : ~ 1/4 of the entire galaxy population (based on results at z~3), but still very important — easier to identify; current redshift record holder is the LAE at z=6.96 (Iye et al. 2006) LAE as probe of the reionization epoch : neutral IGM — Lya line suppressed — LAE number drop (e.g., Marilada-Escude 1998; Malhotra & Rhoads 2001) LAE at z 6 are usually selected at two narrow windows at z=5.7 & 6.5 in order to avoid strong night-sky lines
Evolution of LAE LF from z=5.7 t0 6.5 Malhotra & Rhoads (2004): no evolution seen; IGM ionized up to z=6.5 Haiman & Cen (2005): not necessarily; local HII bubble permits escape of Lya photons and the suppression is not as large; up to 25%
Better Statistics from Subaru Deep Field Shimasaku et al. (2006)Kashikawa et al. (2006) Kashikawa et al. (2006): strong evolution from z=5.7 to z=6.5 ! Significant fraction of HI at z=6.5 ?? WMAP z reion ~ 11.4?
Part II Stellar Masses of Galaxies at z 6
Stellar Mass Assembly History in Early Universe Stellar mass density & SFR density: = ∫ SFR dt Need measurements at rest-frame optical (and beyond) to reduce biases caused by dust extinction and short-lived stars when converting light to mass Study at high-z made possible by Spitzer IRAC GOODS Spitzer Legacy Program has played an important role
HST Chandra Spitzer GOODS: Great Observatories Origins Deep Survey
Chandra Deep Field SouthChandra Deep Field North (HDF-N) 24’ 28’ (2 Million Seconds)(1 Million Seconds) GOODS Fields
CDF-SHDF-N 10’ 16.5’ 10’ 16.5’ (PI. Mauro Giavalisco) HST Treasury Program: ACS B, V, i, z (0.5 to 0.9μm) to near-HDF depth
CDF-S HDF-N (PI. Mark Dickinson) Spitzer Legacy Program: Deepest IRAC 3.6 – 8.0μm & MIPS 24μm
Extensive Supporting Observations
3.6, 5.8, 4.5, 8.0µm 256x256 array 1.2”/pixel 5.12’x5.12’
3.6 μ m4.5 μ m 5.6 μ m8.0 μ m z =5.83 galaxy IRAC Sees z ~ 6 Galaxies in HUDF
z=5.83 z=5.9 z p ~5.9 Three i-drops in HUDF securely detected by IRAC Yan et al. 2005, ApJ, 634, 109
Some high-mass (a few x M sun ) galaxies were already in place by z 6 (age of Universe < 1.0 Gyr) A few hundred Myr old (formed at z>>6) Number density consistent with CDM simulation from Nagamine et al. (2004) Some Major Conclusions from SED Fitting See also Eyles et al. (2005)
CDFS, 3.6 μ mHDFN, 3.6 μ m Extending to Entire GOODS (Yan et al. 2006, ApJ, 651, 24) IRAC-detected i-dropouts
CDFS, 3.6 μ m HDFN, 3.6 μ m IRAC-invisible i-dropouts
274 i’-drops selected by GOODS ACS data (~12 spec-id’ed) Rejecting low-z contaminators --- IRAC-selected Extremely Red Objects (IEROs; Yan et al. 2004): ~17% among the non-blended i’-drops CDF-S HDF-N Sum detected (“IRAC- detected”) invisible (“IRAC- invisible”) blended x 83% 98 (“Blended”) additional contamination due to photometric error 3/13~23% based on HUDF results Basic Statistics
Difficulty: no photometric info between z’ and IRAC 3.6 μ m Have to take a different, simplified approach (z’-3.6 μ m) color age for a given SFH M/L for a given SFH at this age stellar mass; repeat for all SFH in the set, and take min, max, median
Stellar Mass Estimates Summarized IRAC-detected Sample M rep : 0.09 ~ 7.0x10 10 M sun (median 9.5x10 9 M sun ) T rep : 50 ~ 400 Myr (median 290 Myr) IRAC-invisible Sample, using 3.6 m upper limit Upper-limit of M max (median 4.9x10 9 M sun )
IRAC-invisible sample stackRandom stack 3.6 μ m 3.6 μ m mag = median z’ mag = M min = 1.5x10 8 M rep = 2.0x10 8 M sun M max = 5.9x10 9 Stacking of IRAC-invisible i-dropouts
Models courtesy of K. Nagamine; based on simulations of Nagamine et al. (2004) and Night et al. (2006) Implications (I): compare to simulation ΛCDM models seem to be capable of producing such high-mass galaxies by z 6
Implications (II): Global Stellar Mass Density Lower limit at z ~ 6: (1.0, 1.6, 6.5) x 10 6 M sun Mpc -3
Implications (III): Source of Reionization Critical SFR based on Madau et al. (1999) Progenitors of all IRAC- detected z 6 galaxies formed simultaneously with the same e-SFH: SFR e -t/ The progenitors of high-mass galaxies alone CANNOT provide sufficient ionizing photons to sustain the reionization Dwarf (low-mass, low- luminosity) galaxies, which could be more numerous, must have played an important role
Part III Bright-end of LF at z 6
L* & Bright-end of LBG LF Bouwens et al. (2006): L*(z=6) = 0.6L*(z=3) Effect of large-scale structure ( “cosmic variance”)??
Need Degree-sized Surveys to Minimize Impact of “Cosmic Variance” at Bright-end (Millennium Simulation slice at z=5.7)
D1(2h-4d) (overlap SWIRE) D2 (10h+2d) (w/COSMOS) D3 D4 16.5’x10’ GOODS- Size Area Bright i-drops in 4-deg 2 CFHTLS Yan et al. (in prep)
u’ g’ r’ i’ z’ 3.6µm 4.5µm 5.8µm 8.0µm u’ g’ r’ i’ z’ 3.6µm 4.5µm 5.8µm 8.0µm z’-ch1≥3.25; IRAC-selected ERO (IERO; Yan et al. 2004); “red & dead” galaxies at z~2-3 IRAC to Screen Out Interlopers
D1 D2 D3 D4 z’< ≤z’< ≤z’< Total % Yan & Windhorst 04: Bouwens et al. 06: /deg 2 28/deg 2 Much closer to YW04 prediction; the agreement is even better after counting the incompleteness correction at AB~25. Sample Statistics
Magellan High-z LAE Survey Yan, McCarthy & Windhorst
Survey Highlights Narrow-band imaging in 917nm & 971nm OH- free windows to search for LAE at z ≈ 6.5 & 7.0 Four IMACS f/2 fields (~ 0.9 deg 2 ); reducing cosmic variance with limited telescope time Survey depth (5- ) AB=25.0 mag (2.45 erg/s/cm 2 for pure-line sources; 7-8 erg/s/cm 2 for continuum-detected sources) Aiming at bright-end of the luminosity function
6.46 — — 7.07 ~ 400 Mpc 3 /arcmin 2 (Before upgrading, SITe CCDs) o(917nm)p(971nm) Survey Design: Filters
Survey Design: Fields Use fields that have public, deep continuum images in multi-bands (especially in z’-band) Accessibility from Las Campanas CFHTLS Deep D1, D2 & D4 spreading out in RA
Survey Status 1-night in Feb night in Mar. 2008, 1 IMACS pointing in COSMOS field (CFHTLS- D2), 20hr in o(917nm) 3-night in Jul. 2007, 1 IMACS pointing in CFHTLS-D4, 20 hr in o(917nm) Achieved desired depth
COSMOS CFHTLS-D o 1o1o 1o1o
5- source counts CFHTLSD4NW, 20hr in o
LAE Candidate Selection Continuum images from the T0003 release of CFHTLS-D4 z’-o>0.44 (f lin /f con >1.5) i’-z’>1.3 if detected in z’ non-detection in u’,g’ and r’ For now only discussing candidates invisible in z’
3 candidates invisible in continuum o=23.88 o=24.39 o=25.49? (Now seeking time do spectroscopic identification)
Kashikawa et al (in Subaru Deep Field) Rapid Evolution from z=5.7 to 6.6 or not?
Part IV Searching for Galaxies at z > 7-8 and beyond
Deep Space-based IR Imaging for LBG Bouwens & Illingworth (2006); Bouwens et al. (2008)
Space-based IR Imaging around Lensing Clusters for LBG Bradley et al. (2008) Abell 1689
Direct Slit-Spectroscopy around Lensing Clusters for LAE Stark et al. (2007)
Another Line of Thought There might be a much more luminous population at z>7; surface density as high as /arcmin 2 From Yan et al. (2006)
Wide-field near-IR Survey with WIRCam at CFHT PIs. Lihwai Lin & Luc Simard
CFHT WIRCam J, 26 hrs Candidates to be observed by NICMOS in Cy-16 soon (PI. Yan)
WFC3/HST Will Play a Critical Role in the Study of the High-z Universe
Programs with various depths & coverage WFC3 IR FOV 4.6 arcmin2 Ultra-deep program (HUDF- like) to probe the faint-end Wide program (GOODS-like) to probe the L* level Different sight-lines to beat down the cosmic variance — 200-orbit parallel program approved in Cycle- 17 (PI. Yan)
Summary UV Luminosity Function of Galaxies at z 6 — a very steep faint-end slope Stellar Masses of Galaxies at z 6 — some high-mass, “old” galaxies already in place Implications for (HI) Reionization — dwarf galaxies did it! Unanswered Questions at z 6: Bright-end of LF (LBG/LAE) — degree-sized surveys needed to reduce “cosmic variance” Searching for Galaxies at z > 7-8 — very wide-field IR survey from the ground and deep surveys from the space (wait for WFC3!)